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Gursharan Singh Tatla [email protected] DATA LINK PROTOCOLS 24-Mar-2011 1 www.eazynotes.com

Gursharan Singh Tatla [email protected] DATA LINK PROTOCOLS 24-Mar-2011 1

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Gursharan Singh [email protected]

DATA LINK PROTOCOLS

24-Mar-20111 www.eazynotes.com

Data Link ProtocolsData Link Protocols are sets of rule and

regulations used to implement data link layer.

They contain rules for:

Line Discipline

Flow Control

Error Control

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Types of Data Link Protocols

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Data Link Protocols are divided into two categories:

Asynchronous Protocols

Synchronous Protocols

Asynchronous Protocols

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Asynchronous protocols treat each character in a bit stream independently.

These protocols are used in modems.

They use start and stop bits, and variable gaps between characters.

They are slower than synchronous protocols in transmitting data.

Asynchronous Protocols

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The different asynchronous protocols are:

XMODEM

YMODEM

ZMODEM

Block Asynchronous Transmission (BLAST)

Kermit

XMODEM

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It is a half duplex stop & wait protocol.

It is used for telephone line communication between PCs.

The sender sends a frame to receiver & waits for ACK frame.

The receiver can send one cancel signal (CAN) to abort the transmission.

The frame format of XMODEM is:SOH Header Data CRC

1 Byte 2 Bytes

128 Bytes

XMODEM

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The various fields of frame are:

SOH: It is start of header. It is 1 byte field.

Header: It contains the sequence number. It is 2 bytes in length.

Data: This field holds 128 bytes of data.

CRC: It is Cyclic Redundancy Check. This field checks the errors in data field.

YMODEM

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This protocol is similar to XMODEM with the following major differences:

Two cancel signals (CAN) are used to abort the transmission.

The data field is 1024 bytes long.

ITU-T CRC-16 is used for error checking.

ZMODEM

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It is a combination of XMODEM and YMODEM.

BLAST

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BLAST is more powerful than XMODEM.

It is a full duplex protocol.

It uses sliding window flow control.

Kermit

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It is a terminal program as well as file transfer protocol.

It is similar in operation to XMODEM, except that sender has to wait for a negative acknowledgement (NAK) before it starts transmission.

Synchronous Protocols

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Synchronous Protocols take the whole bit stream and divide it into characters of equal size.

These protocols have high speed and are used for LAN, WAN and MAN.

Synchronous protocols are categorized into two groups:

Character-Oriented Protocol

Bit-Oriented Protocol

Character-Oriented Protocol

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It interprets frame as a series of characters.

These are also known as Byte-Oriented Protocols.

Control information is inserted as separate control frames or as addition to existing data frame.

The example of character-oriented protocol is Binary Synchronous Communication (BSC) developed by IBM.

Bit-Oriented Protocol

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It interprets frame as a series of bits.

Control information can be inserted as bits depending on the information to be contained in the frame

Bit-oriented protocol can pack more information into shorter frames.

The examples of bit-oriented protocol are:

Synchronous Data Link Control (SDLC)

High Level Data Link Control (HDLC)

Synchronous Data Link Control (SDLC) Protocol

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SDLC protocol was developed by IBM in 1975.

After developing SDLC, IBM submitted it to American National Standard Institute (ANSI) and to International Standard Organization (ISO) for acceptance.

ANSI modified it to ADCCP (Advanced Data Communication Control Procedure.

ISO modified it to HDLC (High Level Data Link Control).

Synchronous Data Link Control (SDLC) Protocol

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The frame format of SDLC is:

The flag sequence of 8-bits 01111110 marks the beginning and ending of the frame.

Address field contains the address of the receiver.

Control field carries the sequence number, acknowledgement, requests and responses.

Flag Address Control User Data ECF Flag

8-Bit

8-Bit

16-Bit

01111110

01111110

Synchronous Data Link Control (SDLC) Protocol

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The frame format of SDLC is:

The user data field carries the data and is of variable length.

ECF stands for Error Checking Field and is of 16-bits. It is used for error control.

Flag Address Control User Data ECF Flag

8-Bit

8-Bit

16-Bit

01111110

01111110

High Level Data Link Control (HDLC) Protocol

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HDLC came into existence after ISO modified the SDLC protocol.

It is a bit-oriented protocol that supports both half and full duplex communication.

Systems using HDLC are characterized by:

Station Types

Configuration.

Response Modes

Station Types

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To make HDLC protocol applicable to various network configurations, three types of stations have been defined:

Primary Station

Secondary Station

Combined Station

Primary Station

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It has complete control over the link at any time.

It has the responsibility of connecting & disconnecting the link.

The frames sent by primary station are called commands.

Secondary Station

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All the secondary stations work under the control of primary station.

The frames sent by secondary station are called responses.

Combined Station

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A combined station can behave either as primary or as secondary station.

It can send commands as well as responses.

ConfigurationConfiguration defines how the various

stations are connected to a link.

There are three possible configurations:

Unbalanced Configuration

Symmetrical Configuration

Balanced Configuration

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Unbalanced ConfigurationThis type of configuration exists if one

station is primary and other is secondary.

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Unbalanced ConfigurationIt can further be of two types:

Point-to-Point Unbalanced Configuration:

If there is one primary and one secondary station.

Multipoint Unbalanced Configuration:

If there is one primary and many secondary stations.

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Symmetrical Configuration

In this configuration, both sites contain two stations: one primary and one secondary.

Primary station of one site is linked with secondary station of the other and vice versa.

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Primary

Secondary

Primary

Secondary

Command

Response

Command

Response

Site A Site B

Balanced ConfigurationIn this configuration, both sites have

combined stations.

These combined stations are connected with single link.

This single link can be controlled by either station.

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Response ModesHDLC supports three modes of

communication between stations:

Normal Response Mode (NRM)

Asynchronous Response Mode (ARM)

Asynchronous Balanced Mode (ABM)

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Normal Response Mode (NRM)

In this mode, primary station controls the link.

Secondary station seeks permission from primary before transmitting the data.

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Asynchronous Response Mode (ARM)

In this mode, if channel is idle, secondary station may initiate the transmission without seeking permission from the primary.

If any secondary station wants to communicate with other secondary station, the transmission is done via primary station only.

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Asynchronous Balanced Mode (ABM)

This type of mode involves combined stations.

There is no primary-secondary relationship, all stations are equal.

Therefore, either of the combined station can initiate the transmission without seeking permission from the other.

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Frame Structure in HDLCFrame in HDLC can have six fields:

Flag Field: It is the 8-bit field that contains 01111110. It marks the beginning and end of a frame.

Address Field: This field contains the address of the receiver. It is 8-bit long.

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Flag Address Control

Information FCS Flag

01111110 01111110

8-Bit 8-Bit 8/16-Bit Variable 16-Bit 8-Bit

Frame Structure in HDLCFrame in HDLC can have six fields:

Control Field: It carries the sequence number, acknowledgements, requests and responses. It can be of 8-bit or 16-bit.

Information Field: It contains user data. Its length is different for different networks.

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Flag Address Control

Information FCS Flag

01111110 01111110

8-Bit 8-Bit 8/16-Bit Variable 16-Bit 8-Bit

Frame Structure in HDLCFrame in HDLC can have six fields:

FCS Field: FCS stands for Frame Check Sequence. It is the error detection field and is 16-bit long. It contains either 16-bit CRC or 32-bit CRC.

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Flag Address Control

Information FCS Flag

01111110 01111110

8-Bit 8-Bit 8/16-Bit Variable 16-Bit 8-Bit

Types of Frames in HDLCHDLC defines three types of frames:

Information Frame (I-Frame):

I-Frames carry user data, and control information about user’s data.

Supervisory Frame (S-Frame):

S-Frames carry flow & error control information.

Unnumbered Frame (U-Frame):

U-Frames are reserved for system management.

They are used to exchange session management & control information between the two connected devices.

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